DE60319160T2 - CONTROL CIRCUIT FOR DIODE-BASED HF CIRCUITS - Google Patents

Abstract

A control circuit for diode based RF circuit (6) comprising at least one analog communicating device (2, 3) having a plurality of digital control lines (A0, A1, A2, En1, B0, B1, B2, En2), a plurality of selectable poles (X0-X15) and at one common pole (Y1, Y2), the digital control lines being connected to a digital data generator (4) and the selectable poles and at least one common pole being connected to the control terminal(s) of the diode(s) of the RF circuit through a network of resistors (7-21) of differing values and a potential divider (22) and a power supply or voltage source (25) or a network of potential dividers of differing outputs and a power supply or voltage source, the analog communicating device establishing an internal coupling between the common pole and one of the selectable poles depending upon the digital value generated by the digital data generator and appearing at the digital control.

Description

TECHNICAL AREA

The The present invention relates to a control circuit for RF circuits on a diode basis.

electrical Parameters such as attenuation, phase shift or reinforcement diode-based circuits, such as an attenuator, Phase shifter, gain control amplifier or Linearizers are dependent on the RF resistance of the diode (s) therein. Of the RF resistance of the diode varies with the change in diode temperature and thereby causes a change in the electrical parameters of the RF circuits, which is undesirable. The changes of the electrical parameters therefore for controlled a smooth functioning of the RF circuits become. The electrical parameters of the RF circuits can be controlled by one controls the RF resistance of the diode (s), which in turn by controlling of the current flowing through the diode (s) Direct current can be controlled.

STATE OF THE ART

digital Control circuits are used in diode-based RF circuits, to the effect of the temperature of the diode (s) therein on the electric Minimize parameters by the DC current flowing through the diode (s) is controlled.

digital Control circuits include temperature sensors or temperature sensitive ones Elements connected to an ADC (analog-to-digital converter) are a PROM (programmable read-only memory) connected to the ADC or microprocessor and one connected to the PROM or microprocessor DAC (digital-analog control). The output signal of the DAC is connected to the control terminal (or the control terminals) the diode (s) of the RF circuit connected. The temperature sensors will be near the diode (s) arranged. The PROM contains data regarding fluctuations electrical parameter at different temperatures. The temperature sensor measures the temperature of the diode (s) and outputs a signal to the PROM, which is a function of the temperature measured by it. The PROM compares this signal with the data stored therein and gives a signal that modifies the current flowing through the diode so that the desired Value of the electrical parameter regardless of the temperature fluctuations is maintained in the diode or in the diodes. These circuits however, they require many components and have complex construction and are very expensive. Since the temperature sensors only in nearby the diode (s) are arranged, the actual temperature fluctuations not necessarily measured by the sensors. This is more the case when the rf circuits be used at high RF energy levels and the barrier layers to heat the diode (s). This can lead to incorrect control of the current through the diode (s) and the electrical parameter of the RF circuit. If a gradual change the temperature of the diode (s) is present, the input signal of the ADC by a bit-crossing threshold, what about abrupt changes the output signal of the ADC leads. This can cause cyclic oscillations between two output states of the Lead ADC, because circuit noise with low level and power ripple an incorrect control of the electrical parameter of the RF circuit cause.

It can also used analog control circuits in diode-based RF circuits Be aware of the effect of the temperature of the diode (s) in it to minimize the electrical parameters by passing through the diode (s) flowing DC is controlled. Analog control circuits include adjustable ones non-linear circuits to achieve the desired bias point for each Value of the electrical parameter to be controlled. In addition, can A temperature-sensitive element can be used to scale and to change the offset of the circuit to temperature fluctuations to compensate. However, these circuits can only be one specific Type of transfer function and / or only one specific type of temperature compensation function generate and can therefore not for different applications are used. In addition, the calibration is analog circuits via a large temperature range time consuming and difficult.

OBJECTS OF THE INVENTION

A The object of the invention is to provide a control circuit for RF circuits on a diode basis, their electrical parameters regardless of temperature variations can be accurately controlled in the diode or the diodes therein.

A Another object of the invention is to provide a control circuit for rf circuits on Diode base, whose electrical parameters regardless of the temperature fluctuations in the diode or the diodes therein due to a self-heating of the Barrier layers of the diode (s), which by using the RF circuits at high RF energy values can be accurately controlled.

Another object of the invention is to provide a diode-based control circuit for rf circuits in which the use of Tempe temperature sensors is unnecessary, whereby errors due to temperature gradients are eliminated.

A Another object of the invention is to provide a control circuit for rf circuits on Diode based, compact and economical is.

A Another object of the invention is to provide a control circuit for rf circuits on Diode base, which has a simple construction and lightweight to operate.

DESCRIPTION OF THE INVENTION

According to the invention is a control circuit for a diode-based RF circuit is provided, comprising: at least one analog commutation device with several digital control lines, several controllable poles and at least one common pole, wherein the digital control lines to a digital data generator are connected and the controllable poles and at least one common pole to the control terminal (s) of the diode (s) of the RF circuit by a Network of resistors different values and a voltage divider and a power supply or a voltage source or a network of voltage dividers different output power and a power supply or Voltage source are connected, wherein the analog commutation device an internal coupling between the common pole and one of the controllable poles, depending from the digital value generated by the digital data generator is generated and appears on the digital control lines.

According to one embodiment The invention relates to a control circuit with two connected in tandem created analog commutation, wherein the digital Control lines of the two analog Kommutierungsbauelemente to the digital data generator are connected, each of the controllable Pole of the two analog commutation devices except one by a resistor to the control terminal (s) of the diode (s) of the RF circuit is connected, where the resistors have different values and the common pole of the two analog commutation devices connected to the output of a voltage divider, the one Pair of resistors includes different values connected in series, wherein one the resistances connected to the power supply or the power source and the other is grounded.

According to one another embodiment The invention relates to a control circuit with two analog commutation components, which are connected in tandem, created using the digital control lines of the two analog commutation devices to the digital data generator are connected, the controllable poles of the two analog Commutation devices except one to the outputs a network of potential dividers are connected, each one a pair of series connected resistors of different values includes, wherein one of the resistors connected to the power supply or the power source and the other is grounded and the common pole of the two analog Commutation components to the control terminal (s) of the diode (s) of the HF circuit is connected.

According to one embodiment According to the invention, the digital data generator is a four-bit data generator.

According to one embodiment According to the invention, each analogue commutation device is analogous Multiplexer.

According to one embodiment According to the invention, the analog multiplexer comprises four digital control lines and eight controllable poles.

It follows a detailed Description of the invention with reference to the accompanying drawings. Show it:

BRIEF DESCRIPTION OF THE ATTACHED DRAWINGS

1 a circuit diagram of a control circuit for diode-based RF circuits according to an embodiment of the invention;

2 a graphical graph of the output voltage and the output resistance of the control circuit of 1 ; and

3 a circuit diagram of a control circuit for diode-based RF circuits according to another embodiment of the invention.

Regarding 1 In the accompanying drawings, IP is a control circuit with two analog multiplexers 2 and 3 which are connected in tandem. The digital control lines A0, A1, A2 and En1 of the multiplexer 2 and B0, B1 and B2 of the multiplexer 3 are connected to a digital four-bit data generator 4 connected. The control line En2 of the multiplexer 3 is through a NOT gate 5 connected to the data generator. The controllable poles of the multiplexer 2 and 3 are marked with X0 to XI5. The poles Y1 and Y2 of the multiplexers 2 and 3 are each linked together and form a common pole CP. The controllable pole X0 of the multiplexer 2 is left unconnected.

The controllable pole X1 of the multiplexer 2 is through a resistance 7 to a control terminal CT of the diode (s) (not shown) of an RF circuit 6 connected. Similarly, each of the other controllable poles X2 to X15 is the multiplexer 2 and 3 each by resistors 8th to 21 connected to the control terminal CT of the RF circuit. 22 is a voltage divider that is a pair of series connected resistors 23 and 24 includes. The common pole CP is connected to the output of the voltage divider. The resistance 23 is connected to a power supply 24 connected and the resistor 24 is grounded. The digital values on the control lines En1 and En2 of the two multiplexers control the connectivity between the drivable poles and the common pole CP. The four-bit data generator 4 generates sixteen different four-bit digital values from 0000 to 1111. Each of these digital values is stored in a desired value of the electrical parameter, such as attenuation, phase shift or gain of the RF circuit with respect to the resistors 7 - 21 mapped or translated in a known manner. For example, if attenuation is the electrical parameter of the RF circuit containing at least one PIN diode that is to be controlled, one of the digital values 0001 is mapped or translated into a value of attenuation of, for example, 2 dB and so on. Thus, sixteen set points of attenuation can be obtained corresponding to sixteen digital values of the data generator, ie, sixteen different commutation states are obtained. The setpoints of the electrical parameter may have a well-defined, but nonlinear progression, such as 1.13, 2.5, or any progression that is not based on any specific mathematical function, such as 1, 2, 5. Depending on that The digital value output to the data generator becomes one of the controllable poles X0 to X15 of the multiplexer 2 and 3 is selected and a DC coupling path is established from the common pole CP connected to the output of the voltage divider to the selected pole connected to the control terminal CT of the diode (s) of the RF circuit 6 is connected through a corresponding resistor, and a current flows through this established coupling path in the RF circuit. The value of the current flowing into the diode (s) of the RF circuit through the established coupling path is such that the actual value of the electrical parameter of the RF circuit is equal to the set point regardless of the temperature fluctuations in the diode or diodes of the RF circuit of the electrical parameter is comparable. For example, if the setpoint of the electrical parameter, such as attenuation, is 2 dB, one of the sixteen digital values generated by the data generator, such as the digital value 0001, is mapped or translated to the setpoint of 2 dB. When the data generator outputs the digital value 0001, the controllable pole X1 of the multiplexer becomes 2 is selected and there is a DC coupling path from which to the output of the voltage divider 22 connected common pole CP to the controllable pole X1 produced by the resistor 7 is connected to the control terminal of the diode (s) of the RF circuit, and thereby a current can flow into the RF circuit via the DC coupling path. The value of the current is such that the actual value of the RF circuit attenuation is comparable to the 2 dB target regardless of the temperature variations in the diode or diodes of the RF circuit.

To illustrate a typical example, the resistors R7 to R21, R22 and R23 of the resistors 7 to 21 . 23 and 24 which appear in the respective direct current coupling path, are determined as follows:
The RF circuit connected to the control circuit is an attenuator including at least one PIN diode, and the electrical parameter of the attenuator to be controlled by the control circuit is the attenuation over a temperature range of -10 ° C to + 50 ° C. The attenuation setpoints are 0 dB to 30 dB in 2 dB increments, ie 0 dB, 2 dB, ... 28 dB and 30 dB. The data generator is a four-bit data generator that generates sixteen different digital four-bit values from 0000 to 1111. Each of these sixteen digital values is mapped into a desired attenuation value. For example, the digital value 0000 is mapped to the setpoint of 0 dB and the last digital value 1111 is mapped to the setpoint of 30 dB. When the data generator outputs a digital value 0000, the addressable pole X0 is selected and becomes a coupling path from that to the output of the voltage divider 22 connected to X0, but since X0 is left disconnected, no current flows into the attenuator, and the value of attenuation of the attenuator is 0 dB. When the data generator outputs a digital value 0001, the controllable pole X1 is selected and a DC coupling path is established from that to the output of the voltage divider 22 connected CP to X1 made by the resistor 7 is connected to the control terminal of the attenuator, and a current flows through this path in the attenuator. The value of the current flowing through this path is such that the actual value of the attenuation of the attenuator at all temperatures of -10 ° C to + 50 ° C with the target value of the attenuation, ie 2 dB, is comparable. The value of the current flowing into the attenuator is a function of the power supply 25 , the value of the resistors 23 and 24 and the resistance 7 which appear in the coupling path, the temperature of the diode (s) and the electrical characteristic of the attenuator, ie, RF resistance. To get the actual attenuation close to the setpoint of 2 dB are the resistors appearing in the DC coupling path 7 . 23 and 24 very important. The values of these resistors and the other resistors 8th to 21 are calculated using the values of the output voltage and the output resistance of the control circuit for each of the setpoints of attenuation, which in turn are obtained by the calibration procedure given below:
The attenuator is connected to a network analyzer which provides an RF signal to the attenuator and measures the attenuation provided by the attenuator to the RF signal. The attenuator is placed in a temperature-controlled chamber whose temperature is varied from -10 ° C to + 50 ° C. A programmable voltage source is programmed to supply varying voltages to the attenuator. A DMM (digital multimeter) is programmed to measure the current appearing on the attenuator control terminal and the voltage appearing on the attenuator control terminal. The attenuation setpoints are 0 dB to 30 dB with steps of 2 dB, ie 0 dB, 2 dB, 4 dB, 8 dB and finally 30 dB. The first setpoint of attenuation is 2 dB. The network analyzer supplies the RF signal to the attenuator and the temperature of the chamber is maintained at -10 ° C. The programmable voltage source supplies the varying voltage to the control terminal of the attenuator. At the same time, the network analyzer monitors the output power of the attenuator. If the network analyzer indicates an attenuation value of 2 dB, ie the RF signal is attenuated by 2 dB, which is the first attenuation target value, the DMM measures the current Iatt and the voltage Vatt at the attenuator control terminal Values are recorded. The above procedure continues until each of the remaining set points of attenuation, ie 4 dB to 30 dB, is registered in the network analyzer. The values of the voltage Vatt and the current Iatt corresponding to each target attenuation value are measured and recorded. The temperature of the chamber is changed to 20 ° C. The above procedure is repeated. The values of the voltage Vatt and the current Iatt corresponding to each target attenuation value are measured and recorded. The temperature of the chamber is further changed to 50 ° C. The values of the voltage Vatt and the current Iatt corresponding to each target attenuation value are measured and recorded by repeating the above procedure. Each setpoint of attenuation will have three pairs of corresponding current and voltage values, ie Iatt and Vatt, measured and recorded at the three different temperatures -10 ° C, 20 ° C and 50 ° C. For example, 2 dB has three pairs of current and voltage values, the three pairs being (Iatt1, Vatt1), measured and recorded at -10 ° C, (Iatt2, Vatt2), measured and recorded at 20 ° C and (Iatt3, Vatt3) measured and recorded at 50 ° C. These values (Iatt1, Vatt1), (Iatt2, Vatt2) and (Iatt3, Vatt3) are then plotted on a graph ( 2 the attached drawings). Using the method of least squares of squares, the slope and voltage passage of the straight line passing through the points plotted in the above graph are calculated on the basis of the best fit. The straight line passing through the points plotted in the above graph is the output bias line of the control circuit corresponding to 2 dB. The voltage passage is equal to the output voltage Vout of the control circuit and the slope is equal to the reciprocal of the output resistance 1 / Rout1 of the control circuit. A similar output voltage Vout and a similar output resistance Rout of the control circuit for each of the remaining set points of attenuation, ie 4 dB to 30 dB, are calculated using the pairs of voltage and current that were measured and recorded as the network analyzer of these set points of attenuation registered.

The values R23 and R24 of the resistors 23 and 24 are obtained first by solving the following equations: Vab = (constant DC voltage) × R24 / (R23 + R24) Rab = (R23 × R24) / (R23 + R24)

Vab is the value of the output voltage Vout of the control circuit, the for the highest Value of current Iatt was calculated at the control terminal of the attenuator while the calibration process has appeared. This selection tends to minimize errors, because a high value of the current higher Sensitivity to Error in Vout matches.

Rab is any value less than the smallest value of Rout calculated for each of the attenuation setpoints. The values of each of the resistors 7 to 21 can be calculated as below: for example R7 = (Vab - Vattv) / (Iattv - Rab) where Vattv and Iattv are the averages of the respective voltage and current values measured and recorded on the attenuator control terminal as the network analyzer, the nominal attenuation value of 2 dB at the various temperatures of -10 ° C, 20 ° C and 50 ° C has registered. Vattv is the mean of Vatt1, Vatt2 and Vatt3, and Iattv is the mean of Iatt1, Iatt2 and Iatt3. Similarly, the resistance and the values of the resistors 8th to 21 calculated.

The output bias line of the control circuit will be characterized by a calibrated slope 1 / Rout and a calibrated voltage crossing Vout for each of the setpoints of attenuation, ie 0 dB to 30 dB. For example, if the initial bias line shown in the graph (FIG. 2 ), the output bias line is obtained by plotting a line passing through the points (Vatt1, Iatt1), (Vatt2, Iatt2) and (Vatt3, Iatt3) based on the best fit. (Vatt1, Iatt1), (Vatt2, Iatt2) and (Vatt3, Iatt3) are the voltage and current values that appeared on the attenuator control terminal during the calibration procedure. The voltage crossing Vout1 and the slope 1 / Rout1 were calculated by using the method of least squares of the squares. The values of the resistors 7 . 23 and 24 which appear in the coupling path were calculated using the calibrated values Vout1, Rout1 and (Vatt1, Iatt1), (Vatt2, Iatt2) and (Vatt3, Iatt3). At any temperature from -10 ° C to 50 ° C, therefore, the actual current and the actual Iatt and Vatt voltages applied to the attenuator will be limited to this output bias line, thereby increasing the actual value of the attenuation near the setpoint the attenuation of 2 dB is maintained.

The embodiment of 3 and the accompanying drawings include a control circuit Q with two analog multiplexers 2a and 3a which are connected in tandem. The digital control lines A0, A1, A2 and En1 of the multiplexer 2a and B0 and B2 of the multiplexer 3a are connected to a digital four-bit data generator 4a connected. The control line En2 of the multiplexer 3a is through a NOT gate 5a connected to the data generator. The controllable poles of the multiplexer 2a and 3a are marked with X1 to X15. The poles Y1 and Y2 of the multiplexers 2a respectively. 3a are tied together to form a common pole CP1, which in turn connects to the control terminal CP1 of the diode (s) (not shown) of the RF circuit 6a connected. The controllable pole X0 of the multiplexer 2a is left unconnected. Each of the controllable poles X1 to X15 of the multiplexer is at the output of each of the voltage divider 26 to 40 connected. Each of the voltage dividers 26 to 40 includes a pair of resistors 26a and 26b each to 40a and 40b , Each of the resistors 26a to 40a is connected to a power supply 41 connected, and each of the resistors 26b to 40b is grounded. The resistors of the voltage divider have different values. The digital values on the control lines En1 and En2 of the two multiplexers control the connectivity between the drivable poles and the common one pole CP1. The control circuit works in the same way as that of 1 , During operation of the control circuit one of the controllable poles X0 to X1S is selected and a DC coupling path is established from the selected pole connected to the output of a voltage divider to the common pole CP1 which is connected to the control terminal CT1 of the HF Circuit is connected, whereby a corresponding current can flow via the coupling path in the RF circuit. The value of the current flowing into the RF circuit is such that the actual value of the electrical parameter of the RF circuit is close to the desired value of the electrical parameter.

The output voltage Vout and the output resistance Rout for each of the set values of the electrical parameter are obtained by the calibration procedure described above, and the values of the resistors 26a to 40a and 26b to 40b are calculated as described below.

For example, if Vout1 and Rout1 are the output voltage and the output resistance of the control circuit obtained by the calibration procedure for 2 dB, the values of the resistors appearing in the DC coupling path are calculated as follows: Vout 1 = (constant DC voltage) × R26b / (R26a + R26b) Rout 1 = (R26a × R26b) / (R26a + R26b)

Similarly, the values of the other resistors 27a to 40a and 27b to 40b calculated.

According to the invention the control circuit controls the electrical parameter of an RF circuit precise and reliable, since the actual Values of the electrical parameter of the RF circuit during its Operation come close to the setpoints of the electrical parameter. The control circuit controls the electrical parameters of the RF circuits in response to temperature variations in the diodes of the RF circuit. temperature fluctuations in the diode or the diodes due to the self-heating of the Barrier layers of the diode (s) resulting from the use of the RF circuits at high HF energy values does not affect the accuracy of the Control circuit off. By the control circuit of the invention is eliminating the need for temperature sensors, resulting in errors due to be eliminated by temperature gradients. The control circuit of Invention includes only a few components. That's why she is compact and economical. It is also simple and easy to operate in terms of construction.

Depending on The design requirements of the control circuit may be the digital one Data generator selected be that he has more or less digital values compared to generated sixteen digital values. The number of tandem connected Multiplexer may vary accordingly. There can be more than two multiplexers available. The RF circuit can be dependent on the number of its diodes include more than one control terminal, and accordingly, the number the common poles of the analog multiplexer vary. Such Variants are to be understood as falling within the scope of the invention.

Claims (6)

A diode-based RF circuit control circuit comprising: two or more analog commutation devices connected in tandem and having a plurality of digital control lines, a plurality of controllable poles (X ₀ -X ₁₅ ), and at least one common pole (CP); digital control lines to a digital data generator ( 4 ) and the controllable poles and at least one common pole to the control terminal (s) (CT) of the diode (s) of the RF circuit by a) a network of resistors (CT) 8th - 21 ) of different values and a voltage divider ( 22 ) and a power supply ( 25 ) or b) a voltage source or a network of voltage dividers ( 26 - 40 ) are connected to different power outputs and a power supply or voltage source, wherein the analog commutation devices provide an internal coupling between the common pole and one of the controllable poles, depending on the digital value generated by the digital data generator and appearing on the digital control lines. A control circuit according to claim 1, wherein each of said controllable poles of the analog commutation components except one to the control terminal (s) of the diode (s) of the RF circuit connected by resistors is, with the resistors different values are and the common pole of the two analogue Commutation devices are connected to the output of a voltage divider, the one pair of series connected resistors of different values includes, wherein one of the resistors connected to the power supply or the power source and the other is grounded. Control circuit according to claim 1, wherein the controllable Pole of the two analog commutation devices except one to the outputs of the Network of voltage dividers are connected, each one Pair of series connected resistors of different values includes, wherein one of the resistors connected to the power supply or the power source and the other is grounded and the common pole of the two analog Commutation components to the control terminal (s) of the diode (s) of the HF circuit are connected. Control circuit according to one of claims 1 to 3, wherein the digital data generator is a four-bit data generator. Control circuit according to one of claims 1 to 4, wherein each analog commutation device is an analog multiplexer is. Control circuit according to claim 5, wherein the analogue Multiplexer four digital control lines and eight controllable Pole covers.